2015年10月12日西科佩特地区Kenekesir地震(MW = 5.2):余震系列和强地面运动

IF 0.3 Q4 GEOCHEMISTRY & GEOPHYSICS

Seismic Instruments Pub Date : 2022-02-01 DOI:10.3103/S0747923922010091

N. V. Petrova, S. S. Abaseev, L. V. Bezmenova

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引用次数: 1

摘要

本文介绍了2015年克内克西尔地震震源及其余震序列的研究成果。地震发生在阿奇曼-诺库尔构造节点带，在这里，中央Kopet Dag断裂的西北方向转变为西Kopet Dag断裂的东北方向。Kenekesir地震的实际破裂面是根据震源机制、余震群的三维方向、最近断层的方向和以往地震的首次等震线的数据集确定的。断裂面走向西南，向西北倾斜。位移类型为斜滑，具有等量的正断层和左旋走滑分量。该余震系列持续186 d，共发生代表性震级(KR≥5.6)余震1249次。在其初始阶段，确定了11天的余震过程规律发展周期，此时符合Omori定律，相关系数最高，余震衰减参数p = 1.35。此时，余震过程呈现脉动特征，进入介质应力松弛阶段。Kenekesir地震及其余震的加速度和速度图对于评估该地区的地震危险性无疑是有意义的。结果表明，由速度(IPGV)和地震波功率(IPGA⋅PGV)确定的仪器强度与区域大地震场方程吻合度最高。

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Kenekesir Earthquake of October 12, 2015 (MW = 5.2) in the Western Kopet Dag: Aftershock Series and Strong Ground Motions

The article presents the results of studying the source of the 2015 Kenekesir earthquake and its aftershock sequence. The earthquake occurred in the Archman–Nokhur tectonic node zone, where the northwest orientation of the Central Kopet Dag faults changes to the northeast orientation of the Western Kopet Dag faults. The actual rupture plane at the Kenekesir earthquake was determined from the dataset of the focal mechanism, three-dimensional orientation of the aftershock cluster, orientation of the nearest faults, and first isoseismals of previous earthquakes. The rupture plane strikes southwest and dips to the northwest. The displacement type is oblique slip with equal normal-fault and left-lateral strike-slip components. The aftershock series lasted 186 days and consisted of 1249 aftershocks of the representative level (K_R ≥ 5.6). At its initial stage, the 11-day period of regular development of the aftershock process is identified, when the Omori law is fulfilled with the highest correlation coefficient and aftershock attenuation parameter p = 1.35. Then, the aftershock process assumes a pulsating character, passing to the stage of stress relaxation in the medium. Accelerograms and velocigrams of the Kenekesir earthquake and its aftershocks are of undoubted interest for assessing the seismic hazard in this area. It was found that the instrumental intensities determined from the velocity (I_PGV) and seismic wave power (I_{PGA ⋅ PGV}) agree the best with the regional macroseismic field equation.

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来源期刊

Seismic Instruments GEOCHEMISTRY & GEOPHYSICS-

自引率

44.40%

发文量

期刊介绍： Seismic Instruments is a journal devoted to the description of geophysical instruments used in seismic research. In addition to covering the actual instruments for registering seismic waves, substantial room is devoted to solving instrumental-methodological problems of geophysical monitoring, applying various methods that are used to search for earthquake precursors, to studying earthquake nucleation processes and to monitoring natural and technogenous processes. The description of the construction, working elements, and technical characteristics of the instruments, as well as some results of implementation of the instruments and interpretation of the results are given. Attention is paid to seismic monitoring data and earthquake catalog quality Analysis.